KR20230080871A - Blocking foreign substances in the seat long rail and hidden wiring structure - Google Patents

Abstract

The present invention relates to a foreign substance entry blocking and hidden wiring structure for a long seat rail which positions wiring in an internal space of a lower cover to prevent the wiring from being exposed to the outside. The foreign substance entry blocking and hidden wiring structure for a long seat rail comprises: a lower rail fixed on a vehicle body, and including a slot part on an upper portion thereof; a block guide provided to protrude out of the slot part, wherein a portion thereof is positioned on the lower rail; an upper rail positioned on the upper end of the lower rail, and provided to be fastened to the block guide; a plurality of slide blocks formed at a position corresponding to the slot part, and provided to open the slot part at a position corresponding to the upper rail; and a block guide pin formed on the upper surface of the block guide, and provided to allow the slide block to open and close the slot part in accordance with the movement of the upper rail.

Description

Blocking foreign substances in the seat long rail and hidden wiring structure}

The present invention relates to a seat long rail foreign matter inflow prevention and hidden wiring structure, and more preferably, by applying a slide block that closes the slot portion of the lower rail to block foreign matter inflow and at the same time to wire the inner space of the lower cover It relates to a seat long rail foreign matter inflow prevention and hidden wiring structure configured to be positioned so as not to be exposed to the outside.

In general, a seat of a vehicle is mounted so as to slide in the front and rear directions of a vehicle body, and a seat rail plays a role thereof. In the case of a passenger vehicle with 2 rows of seats, a short rail is applied to move the driver's seat and the front passenger's seat, and in the case of a recreational vehicle with 2 or more rows of seats, the first and second rows of seats are It is common to apply a short rail and apply a long rail to a longer seat to move the seat.

Here, the seat rail of the vehicle is configured so that the upper rail combined with the seat cushion frame can slide along the lower rail coupled to the floor panel of the vehicle body, and also includes a lock mechanism that restricts the free movement of the upper rail. .

In addition, the forward and backward movement device is driven by a motor so that the forward and backward movement function of the seat can be used more conveniently. In particular, in order to move the upper rail back and forth using a motor, a wire that applies power to the motor and transmits a control signal to move the upper rail is required. A set is called a wiring harness.

On the other hand, the interior of a car in the era of self-driving cars has meaning as a space where you can read, rest, and work to your heart's content in the car with the concept of a moving space. Since there is a seat at the center of this space, changes in the mechanism such as a swivel mechanism that rotates the driver's seat 180 degrees to be converted to conference mode and a long slide that moves the seat to be converted to loading mode are noticeable.

In the autonomous vehicle seat, the power long rail is embedded under the carpet, and the stroke of the rail is increased to improve passenger convenience. At this time, the exposed section of the lower rail slit of the seat and the wiring also increases in proportion to the increase in the stroke. Due to this, there is a problem in that foreign substances may be introduced through the slit portion of the exposed lower rail and damage may be caused by any external force applied to the exposed wiring.

Patent Document 1: Korean Patent Registration No. 10-2241156

The present invention has been made to solve the above problems, and provides a seat long rail foreign matter inflow prevention and hidden wiring structure equipped with a slide block that closes the slot portion of the lower rail.

In addition, a seat long rail foreign matter inflow blocking structure and a hidden wiring structure configured not to be exposed to the outside by locating the wiring in the inner space of the lower cover are provided.

The objects of the present invention are not limited to the above-mentioned objects, and other objects of the present invention not mentioned above can be understood by the following description and can be more clearly understood by the embodiments of the present invention. Also, the objects of the present invention may be realized by the means and combinations indicated in the claims.

In order to achieve the object of the present invention described above, the long rail foreign matter inflow blocking and hidden wiring structure includes the following configurations.

In one embodiment of the present invention, a lower rail fixed to a vehicle body and including a slot portion at an upper portion; a block guide having a portion located on the lower rail and protruding outward from the slot portion; an upper rail positioned on top of the lower rail and configured to be fastened to the block guide; a plurality of slide blocks formed at a position corresponding to the slot part and configured to open the slot part at a position corresponding to the upper rail; and a block guide pin formed on an upper surface of the block guide and configured to allow the slide block to open and close the slot portion according to movement of the upper rail. It provides a seat long rail foreign matter inflow blocking and hidden wiring structure configured to include.

In addition, a lower cover extending along an upper surface of the lower rail and having a slit portion formed on an inner surface thereof; a wiring unit located on an inner surface of the lower cover; and an upper cover extending along an upper surface of the lower cover. And, as the upper rail moves, the slide block at a position corresponding to the upper rail is inserted into the slit portion to provide a seat long rail foreign matter inflow blocking and hidden wiring structure.

In addition, the slit portion is located adjacent to the upper cover, the wiring slit portion into which the wiring portion is inserted; and a block slit portion positioned adjacent to the wiring slit portion and into which the slide block is inserted. The block slit portion includes a left slit portion formed on a left side with respect to the slot portion; and a right slit portion formed on a right side of the slot portion. Provides a seat long rail foreign matter inflow blocking and hidden wiring structure configured to include.

In addition, the wiring unit may include a wiring connector fastened to the driving unit of the upper rail; and wiring that conducts electricity with the vehicle body; It provides a seat long rail foreign matter inflow blocking and hidden wiring structure configured to include.

In addition, a guide groove in an oblique direction on the rear surface of the slide block; is formed, and the block guide pin moves along the guide groove to provide a seat long rail foreign matter inflow prevention and hidden wiring structure configured to insert the slide block into the block slit portion.

In addition, the guide groove includes an oblique portion configured to move the block guide pin in an oblique direction; and a connecting portion located at both ends of the oblique portion and configured to move the block guide pin in a longitudinal direction; Including, wherein the block guide pin is formed at a position corresponding to the connecting portion, a first block guide pin located on one side of the first direction of the block guide adjacent to the left slit portion; and a second block guide pin formed at a position corresponding to the connection part and positioned on the other side of the block guide in the second direction adjacent to the right slit part. It provides a seat long rail foreign matter inflow blocking and hidden wiring structure configured to include.

In addition, the first block guide pin is configured to move to the connecting portion adjacent to the first direction of the block guide, and the second block guide pin is configured to move to the connecting portion adjacent to the second direction of the block guide sheet long rail It provides a structure to block the inflow of foreign substances and hidden wiring.

In addition, when the upper rail moves in the first direction, the first block guide pin moves in the slanted portion, the slide block is inserted into the left slit portion, and the second block guide pin moves in the slanted portion. Thus, the slide block is configured to move to the upper surface of the slot part, and provides a structure for blocking the inflow of foreign substances and hidden wiring in the seat long rail.

In addition, when the upper rail moves in the second direction, the first block guide pin moves to the oblique portion, the slide block moves to the upper surface of the slot portion, and the second block guide pin moves to the oblique portion, The slide block provides a structure for blocking the inflow of foreign substances and a hidden wiring structure of the seat long rail configured to be inserted into the right slit portion.

In addition, when the upper rail moves in the longitudinal direction, the wiring is configured to move along the inner side of the wiring slit portion to provide a structure for blocking the inflow of foreign substances and a hidden wiring structure of the seat long rail.

The present invention can obtain the following effects by the configuration, combination, and use relationship to be described below with the previous embodiment.

The present invention has an effect of preventing damage to the rail by blocking the inflow of foreign substances by mounting a slide block that closes the slot portion of the lower rail.

In addition, since the wiring is positioned in the inner space of the lower cover so that it is not exposed to the outside, damage to the wiring can be prevented.

1 is an embodiment of the present invention, showing a perspective view of a seat long rail foreign matter inflow blocking and hidden wiring structure.
FIG. 2A is a perspective view of an upper rail having a seat long rail foreign matter inflow blocking structure and a hidden wiring structure moving in a first direction according to an embodiment of the present invention. Referring to FIG.
FIG. 2B is a perspective view of an upper rail having a seat long rail foreign matter inflow blocking structure and a hidden wiring structure moving in a first direction and then switching to a second direction according to an embodiment of the present invention.
3 shows a perspective view of a slide block having a seat long rail foreign matter inflow blocking and hidden wiring structure as an embodiment of the present invention.
Figure 4 shows a state before the block guide pin is inserted into the connection part of the seat long rail foreign matter inflow blocking and hidden wiring structure as an embodiment of the present invention.
5 illustrates a block guide, a first block guide pin, and a second block guide pin having a seat long rail foreign matter inflow blocking and hidden wiring structure as an embodiment of the present invention.
FIG. 6 illustrates an upper cover, a wiring unit, and a lower cover having a structure of preventing inflow of foreign substances in a long sheet rail and hidden wiring according to an embodiment of the present invention.
7 is a cross-sectional view of a wiring slit part and a block slit part of a sheet long rail foreign material inflow blocking and hidden wiring structure according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the following examples. This embodiment is provided to more completely explain the present invention to those skilled in the art.

In addition, terms such as "... unit" described in the specification mean a unit that processes at least one function or operation, which may be implemented as hardware or a combination of hardware.

In addition, in this specification, "height direction", "width direction", and "length direction" are based on the vehicle.

Also, in the present specification, "first direction" means forward in the longitudinal direction, and "second direction" means rearward in the longitudinal direction.

In addition, in the present specification, "left" means the left side in the width direction with respect to the slot portion 110 when viewed in the second direction, and "right" refers to the slot portion 110 when viewed in the second direction. It means the right side in the width direction based on .

In addition, in this specification, the names of the components are divided into first, second, etc. in order to classify them based on the relationship in which the names of the components are the same, and the order is not necessarily limited in the following description.

In addition, when a part is said to be "on" or "above" another part in this specification, it includes the case where another part is in the middle as well as the case where it is "directly on" another part. In addition, when a part is said to be "below" or "below" another part, this includes not only the case of being "directly below" the other part, but also the case of another part in the middle.

1 shows a perspective view of a sheet long rail foreign matter inflow blocking and hidden wiring structure as an embodiment of the present invention, and FIG. 2a is a seat long rail foreign matter inflow blocking and hidden wiring structure as an embodiment of the present invention. Figure 2b shows a perspective view when the upper rail of the structure is moved in a first direction, and FIG. 2B is an embodiment of the present invention, after the upper rail of the seat long rail foreign matter inflow blocking and hidden wiring structure moves in the first direction, A perspective view at the time of switching to two directions is shown.

1, 2a and 2b, the seat long rail foreign matter inflow blocking and hidden wiring structure according to an embodiment of the present invention is a lower rail 100, a block guide 200, an upper rail 300 , It may be configured to include a slide block 400 and a block guide pin 500.

The lower rail 100 may be configured to be fixed to a vehicle body. More preferably, the lower rail 100 may extend in the longitudinal direction inside the vehicle body floor panel and be fixedly installed. The lower rail 100 may be configured to include a slot portion 110 thereon.

The slot portion 110 may refer to an open groove present in the upper portion of the lower rail 100 . More preferably, the slot portion 110 may be configured to be visible through an opening of the floor panel. The slot portion 110 extends along the longitudinal direction of the upper surface of the lower rail 100 and may be a passage through which the sheet slides in the longitudinal direction.

A part of the block guide 200 is positioned on the lower rail 100 and may be configured to protrude outward from the slot portion 110 . More preferably, the block guide 200 extends in the longitudinal direction along the lower rail 100 and may be configured to protrude outward from the top of the slot portion 110 .

The upper rail 300 may be positioned on top of the lower rail 100 and fastened to the block guide 200 . More preferably, the upper rail 300 may be formed to be spaced apart from the lower rail 100 and may be configured to slide along the lower rail 100 by being partially engaged with the block guide 200 . The upper rail 300 may be configured to slide and move the seat by being connected to the seat of the vehicle.

A plurality of slide blocks 400 may be formed at positions corresponding to the slot portion 110 . More preferably, the slide block 400 may be configured such that the slot portion 110 corresponding to the upper rail 300 is opened. The slide block 400 at a position that does not correspond to the upper rail 300 may be configured to be positioned on the upper surface of the slot portion 110 . By placing the slide block 400 on the upper surface of the slot portion 110, foreign matter may be prevented from being introduced through the slot portion 110 at a position corresponding to the position of the upper rail 300. Through this, damage to operating functional components inside the lower rail 100 can be prevented. In addition, the slide block 400 may be configured to include an elastic body so that it can be supported after moving in the width direction.

The block guide 200 may be configured to move the slide block 400 . More preferably, the block guide 200 may be configured to move the slide block 400 in the width direction. The slide block 400 may be configured to move in the width direction so that the slot portion 110 is opened and closed.

Block guide pin 500 may be formed on the upper surface of the block guide (200). More preferably, the block guide pin 500 may be configured such that the slide block 400 opens and closes the slot portion 110 according to the movement of the upper rail 300 .

The block guide pin 500 includes a first block guide pin 510 positioned on one side of the block guide 200 in the first direction and a second block guide pin positioned on the other side of the block guide 200 in the second direction ( 520) may be configured to include. More preferably, the first block guide pin 510 may be configured to move the slide block 400 in the first direction relative to the upper rail 300 . The second block guide pin 520 may be configured to move the slide block 400 in the second direction relative to the upper rail 300 .

When the upper rail 300 is moved, the slide block 400 in the first direction and the slide block 400 in the second direction may move in the width direction based on the upper rail 300 . More preferably, when the slide block 400 in the first direction relative to the upper rail 300 moves to the left relative to the slot portion 110, the slide block 400 in the second direction relative to the slot portion 110 It can be configured to move to the right.

The seat long rail foreign matter blocking and hidden wiring structure according to an embodiment of the present invention may be configured to further include a lower cover 700, a wiring unit 800, and an upper cover 900. The wiring unit 800 may be positioned on the lower cover 700 and the upper cover 900 may be assembled to be positioned above the lower rail 100 .

The lower cover 700 may extend along the upper surface of the lower rail 100 . More preferably, the lower cover 700 may be configured such that the slit portion 600 is formed on the inner surface. The slit portion 600 may be configured to correspond to the shape of the wiring portion 800 .

The wiring unit 800 may be located on an inner surface of the lower cover 700 . More preferably, the wiring part 800 may be configured to be located in the slit part 600 of the lower cover 700 . When the upper rail 300 is moved, the wiring part 800 may be configured to move along the shape of the slit part 600 . When the upper rail 300 moves, the wiring part 800 moves along the slit part 600 so as not to interfere with the movement of the sheet.

The upper cover 900 may extend along the upper surface of the lower cover 700 . More preferably, the upper cover 900 may extend from both side surfaces of the slot portion 110 . The upper cover 900 may be positioned above the wiring unit 800 so that the wiring unit 800 is not exposed to the outside.

As the upper rail 300 moves, the slide block 400 at a position corresponding to the upper rail 300 may be inserted into the slit portion 600 . More preferably, the slit portion 600 may include a wiring slit portion 610 into which the wiring portion 800 is inserted and a block slit portion 620 into which the slide block 400 is inserted. The wiring slit portion 610 may be positioned adjacent to the upper cover 900 in the height direction. The block slit portion 620 may be positioned adjacent to the wiring slit portion 610 in the height direction. As the upper rail 300 moves, the wiring part 800 may move along the wiring slit part 610, and the slide block 400 may be inserted into the block slit part 620.

The block slit portion 620 may include a left slit portion 621 and a right slit portion 622 . The left slit portion 621 may be formed on the left side of the slot portion 110 in the width direction. The right slit portion 622 may be formed on the right side of the slot portion 110 in the width direction.

When the upper rail 300 moves, the slide block 400 in the first direction can be inserted into the left slit portion 621 based on the upper rail 300, and the slide block 400 in the second direction can be inserted into the right slit portion. (622). Referring to FIG. 2A , when the upper rail 300 slides in the first direction, the slide block 400 in the first direction may be inserted into the left slit 621 . In addition, when the upper rail 300 slides in the first direction, the slide block 400 in the second direction inserted into the right slit portion 622 may move to the upper surface of the slot portion 110. .

As another embodiment, referring to FIG. 2B , when the upper rail 300 is switched to the second direction while moving in the first direction, the slide block 400 in the first direction inserted into the left slit 621 and the slide block 400 in the right side The slide block 400 in the second direction inserted into the slit portion 622 may coexist. More preferably, the first direction slide block 400 and the second direction slide block 400 in the length area of the block guide 200 may be inserted in opposite directions.

When the upper rail 300 moves in the first direction, the first block guide pin 510 may be configured to insert the slide block 400 into the left slit portion 621 . When the upper rail 300 moves in the first direction, the second block guide pin 520 may be configured to move the slide block 400 to the upper surface of the slot portion 110 .

Meanwhile, when the upper rail 300 moves in the second direction, the first block guide pin 510 may be configured to move the slide block 400 to the upper surface of the slot portion 110 . When the upper rail 300 moves in the second direction, the second block guide pin 520 may be configured to insert the slide block 400 into the right slit portion 622 .

When the upper rail 300 moves in the first direction or the second direction, the slide block 400 moves in the width direction to open the upper surface of the slot portion 110 corresponding to the upper rail 300, and the upper rail 300 ) and may be configured to close the upper surface of the slot portion 110 at a position that does not correspond.

3 shows a perspective view of a slide block 400 having a seat long rail foreign matter inflow blocking and hidden wiring structure as an embodiment of the present invention, and FIG. 4 shows a sheet long rail foreign matter as an embodiment of the present invention. It shows a state before the block guide pin 500 is inserted into the connection part 412 of the inflow blocking and hidden wiring structure, and FIG. It shows the structure of the block guide 200, the first block guide pin 510, and the second block guide pin 520.

Referring to FIGS. 3 to 5 , an oblique guide groove 410 may be formed on the rear surface of the slide block 400 . The guide groove 410 may be configured to allow the block guide pin 500 to move. The block guide pin 500 may move along the guide groove 410 so that the slide block 400 is inserted into the block slit portion 620 . The front surface of the slide block 400 may be formed flat to close the upper surface of the slot unit 110 .

The guide groove 410 may be configured to include an oblique portion 411 and a connection portion 412 . The oblique portion 411 may be configured such that the block guide pin 500 moves in an oblique direction. The connection part 412 is located at both ends of the oblique part 411, and the block guide pin 500 may be configured to move in the longitudinal direction.

The block guide pin 500 may be configured to be introduced into the guide groove 410 and move in a longitudinal direction along the connection portion 412 and then move in an oblique direction along the oblique portion 411 . After the slide block 400 moves in the longitudinal direction, it moves in an oblique direction, and then moves in the longitudinal direction again to be completely inserted into the block slit portion 620 or to completely close the upper surface of the slot portion 110 . Adjacent slide blocks 400 may be configured to move continuously in the longitudinal or transverse direction.

The block guide pin 500 may be formed at a position corresponding to the connecting portion 412 . The block guide pin 500 may be inserted into the connecting portion 412 to move the slide block 400 in the longitudinal direction. The first block guide pin 510 may be located on one side of the block guide 200 adjacent to the left slit portion 621 in the first direction. The second block guide pin 520 may be located on the other side in the second direction of the block guide 200 adjacent to the right slit portion 622 .

The first block guide pin 510 may move in the first direction and adjacent connection portion 412 of the block guide 200 . The first block guide pin 510 may be configured to move the slide block 400 adjacent to the block guide 200 to the upper surface of the slot portion 110 or to be inserted into the left slit portion 621 . The second block guide pin 520 may move in the second direction and adjacent connection portion 412 of the block guide 200 . The second block guide pin 520 may be configured to move the slide block 400 adjacent to the block guide 200 to the upper surface of the slot portion 110 or to be inserted into the right slit portion 622 .

When the upper rail 300 moves in the first direction, the first block guide pin 510 moves toward the oblique portion 411 so that the slide block 400 is inserted into the left slit portion 621. can The first block guide pin 510 may be configured to completely insert the slide block 400 into the left slit portion 621 by moving from one end of the connection portion 412 to the other end of the connection portion 412 . On the other hand, when the upper rail 300 moves in the first direction, the second block guide pin 520 moves to the oblique portion 411 and the slide block 400 is configured to move to the upper surface of the slot portion 110. It can be. The second block guide pin 520 may be configured to move from one end of the connection part 412 to the other end of the connection part 412 so that the slide block 400 completely closes the upper surface of the slot part 110 .

When the upper rail 300 moves in the second direction, the first block guide pin 510 moves toward the oblique portion 411 so that the slide block 400 moves toward the upper surface of the slot portion 110. there is. The first block guide pin 510 may be configured to completely close the top surface of the slide block 400 by moving from one end of the connection part 412 to the other end of the connection part 412 . Meanwhile, when the upper rail 300 moves in the second direction, the second block guide pin 520 moves toward the oblique portion 411 so that the slide block 400 is inserted into the right slit portion 622. can be configured. The second block guide pin 520 may be configured to completely insert the slide block 400 into the right slit portion 622 by moving from one end of the connection portion 412 to the other end of the connection portion 412 .

6 shows an upper cover 900, a wiring unit 800, and a lower cover 700 having a seat long rail foreign matter inflow blocking and hidden wiring structure as an embodiment of the present invention, and FIG. 7 shows the present invention As an example, a cross-sectional view of a wiring slit portion and a block slit portion 620 of a sheet long rail foreign matter inflow blocking and hidden wiring structure is shown.

Referring to FIGS. 6 and 7 , a wiring unit 800 may include a wiring connector 810 and a wiring 820 . The wiring connector 810 may be configured to be coupled with the driving unit of the upper rail 300 . The upper rail 300 may be driven by a driving unit such as a motor. Power may be supplied to the driving unit from a battery by a user's switch operation, and the upper rail 300 may be configured to slide in a first direction or a second direction by the driving unit.

The wiring 820 may be configured to conduct electricity with the vehicle body. More preferably, the wiring 820 may be configured to provide a power signal or a control signal to the driver of the upper rail 300 . The wiring 820 includes main wiring related to interior loads, control wiring, extension wiring related to door structures, wiring applied to airbags, It may be engine room load related wiring (engine wiring), trunk room load related wiring (rear wiring), and the like. When the upper rail 300 moves in the longitudinal direction, the wiring 820 may be configured to move along the inner side of the wiring slit 610 .

The shape of the wiring slit portion 610 may be configured to correspond to the shape of the wiring 820 . When the upper rail 300 moves in the first direction or the second direction, the wiring slit portion 610 may be configured so that the wiring 820 does not interfere with the wiring slit portion 610 . The block slit portion 620 may be located below the wiring slit portion 610 and formed on both sides of the slot portion 110 . The block slit portion 620 may be configured to correspond to the shape of the slide block 400 .

In summary, the present invention blocks the inflow of foreign substances by applying the slide block 400 that closes the slot portion 110 of the lower rail 100 and at the same time inserts the wiring 820 into the inner space of the lower cover 700 Provides a seat long rail foreign substance inflow blocking and hidden wiring structure configured to be positioned so as not to be exposed to the outside.

The above detailed description is illustrative of the present invention. In addition, the foregoing is intended to illustrate and describe preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications are possible within the scope of the concept of the invention disclosed in this specification, within the scope equivalent to the disclosed contents and / or within the scope of skill or knowledge in the art. The described embodiment describes the best state for implementing the technical spirit of the present invention, and various changes required in specific application fields and uses of the present invention are also possible. Therefore, the above detailed description of the invention is not intended to limit the invention to the disclosed embodiments. Also, the appended claims should be construed to cover other embodiments as well.

100: lower rail
110: slot portion
200: block guide
300: upper rail
400: slide block
410: guide groove
411: oblique part
412: connection part
500: block guide pin
510: first block guide pin
520: second block guide pin
600: slit part
610: wiring slit unit
620: block slit unit
621: left slit
622: right slit
700: lower cover
800: wiring unit
810: wiring connector
820: wiring
900: upper cover

Claims (10)

a lower rail fixed to the vehicle body and including a slot portion at an upper portion;
a block guide having a portion located on the lower rail and protruding outward from the slot portion;
an upper rail positioned on top of the lower rail and configured to be fastened to the block guide;
a plurality of slide blocks formed at a position corresponding to the slot part and configured to open the slot part at a position corresponding to the upper rail; and
a block guide pin formed on an upper surface of the block guide and configured to allow the slide block to open and close the slot portion according to movement of the upper rail; configured to include
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 1,
a lower cover extending along an upper surface of the lower rail and having a slit portion formed on an inner surface thereof;
a wiring unit located on an inner surface of the lower cover; and
an upper cover extending along an upper surface of the lower cover; including,
According to the movement of the upper rail, the slide block at a position corresponding to the upper rail is configured to be inserted into the slit portion
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 2,
The slit part
a wiring slit portion positioned adjacent to the upper cover and into which the wiring portion is inserted; and
a block slit portion positioned adjacent to the wiring slit portion and into which the slide block is inserted; including,
The block slit part
a left slit portion formed on a left side of the slot portion; and
a right slit portion formed on a right side of the slot portion; configured to include
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 3,
The wiring unit may include a wiring connector fastened to the driving unit of the upper rail; and
wiring that conducts electricity with the vehicle body; configured to include
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 3,
a guide groove in an oblique direction on the rear surface of the slide block; is formed,
The block guide pin is configured to move along the guide groove so that the slide block is inserted into the block slit portion
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 5,
The guide groove is
an oblique portion configured to move the block guide pin in an oblique direction; and
connecting parts located at both ends of the oblique part and configured to move the block guide pin in the longitudinal direction; including,
The block guide pin,
a first block guide pin formed at a position corresponding to the connecting portion and positioned on one side of the block guide in a first direction adjacent to the left slit portion; and
a second block guide pin formed at a position corresponding to the connection part and located on the other side of the block guide in the second direction adjacent to the right slit part; configured to include
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 6,
The first block guide pin is configured to move to the connection portion adjacent to the first direction of the block guide, and the second block guide pin to move to the connection portion adjacent to the second direction of the block guide
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 7,
When the upper rail moves in the first direction,
The first block guide pin is moved to the oblique portion and the slide block is inserted into the left slit portion,
The second block guide pin is moved to the slanted portion and the slide block is configured to move to the upper surface of the slot portion
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 7,
When the upper rail moves in the second direction,
The first block guide pin moves to the oblique portion and the slide block moves to the upper surface of the slot portion,
Wherein the second block guide pin is moved to the oblique portion and the slide block is configured to be inserted into the right slit portion
Seat long rail foreign substance inflow blocking and hidden wiring structure.
According to claim 4,
When the upper rail moves in the longitudinal direction, the wiring is configured to move along the inside of the wiring slit portion
Seat long rail foreign substance inflow blocking and hidden wiring structure.

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